A common component library aids engineering integration.

As I mentioned in my column last month, PCB design best practices have five pillars. The first pillar, digitally integrated and optimized, is the foundation. It specifically addresses interactions within the design process and how multidiscipline and multidomain integration and collaboration should take place.

This leads me to pose a simple question: Is your engineering team digitally integrated and optimized when it comes to MCAD-ECAD co-design, or is it functioning with a legacy approach that contains many manual efforts/tasks while team members are working in silos?

Every PCB design starts with the design of the physical package/box (the system) where the PCB will reside. As this occurs, the physical features of the PCB are defined. These features include items such as the dimensions of the PCB outline; board thickness; mounting holes; tooling holes; restricted areas/rooms such as specific components' height ceilings; component keep-ins and keep-outs; critical components such as connectors, heatsinks and sub-assemblies; plus any other pertinent critical features and or details.

Read more: MCAD-ECAD Co-design

Our newest column shares tips and tricks and lessons learned over 30 years in PCB design.

With today's complex printed circuit board (PCB) designs challenging us at almost every stage of the design process, along with shortened project schedules and shrinking budgets, achieving success is no easy feat. Smaller component packages, faster signal edge rates or rise times, and increased design for manufacturing (DfM) challenges all make it difficult to achieve success and get product to market on time and under budget. The foundation for achieving success is understanding PCB design (the full design process) and mastering the power of today's EDA tools.

Even so, design teams can lose valuable time on unproductive tasks. Designers need a collaborative approach to electronic systems design that keeps them connected through all engineering disciplines and gives them best-in-class solutions to handle complexity across the entire PCB design process.

Read more: The 5 Pillars of PCB Design Best Practices